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A magnet configuration comprising a pair of Halbach arrays magnetically and structurally connected together are positioned with respect to each other so that a first component of their fields substantially cancels at a first plane between them, and a second component of their fields substantially ad

A magnet configuration comprising a pair of Halbach arrays magnetically and structurally connected together are positioned with respect to each other so that a first component of their fields substantially cancels at a first plane between them, and a second component of their fields substantially adds at this first plane. A track is located between the pair of Halbach arrays and a propulsion mechanism is provided for moving the pair of Halbach arrays along the track. When the pair of Halbach arrays move along the track and the track is not located at the first plane, a current is induced in the windings and a restoring force is exerted on the pair of Halbach arrays.

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1. A track, comprising at least one section of laminated sheets of slotted conductor, wherein said slots are terminated at their ends to provide a path for return currents and wherein said slots have a length that is at least minimally wider than the width of a levitation magnet assembly on a moving

1. A track, comprising at least one section of laminated sheets of slotted conductor, wherein said slots are terminated at their ends to provide a path for return currents and wherein said slots have a length that is at least minimally wider than the width of a levitation magnet assembly on a moving vehicle that rides on said track. 2. The track of claim 1, wherein each conductor is loaded with ferromagnetic material. 3. The track of claim 1, wherein said at least one section of laminated sheets of slotted conductor comprises a plurality of parallel sections of laminated sheets of slotted conductor. 4. The track of claim 3, wherein said plurality of parallel sections comprises three parallel sections. 5. The track of claim 1, wherein said track is configured to provide a centering force. 6. The track of claim 1, said levitation magnet assembly further comprising a magnet configuration, including a first Halbach array having a first magnetic field and a second Halbach array having a second magnetic field, wherein said first Halbach array and said second Halbach array are magnetically and structurally connected together to form a first pair of Halbach arrays, wherein said first Halbach array comprises magnet configurations positioned with respect said second Halbach array and said second Halbach array comprises magnet configurations positioned with respect said first Halbach array such that a first component of said first magnetic field and a first component of said second magnetic field substantially cancel at a first plane between said first Halbach array and said second Halbach array, and a second component of said first magnetic field and a second component of said second magnetic field substantially add at said first plane; and a propulsion mechanism for moving said first pair of Halbach arrays along said track, wherein when said first pair of Halbach arrays move along said track and said track is not located at said first plane, a current is induced in said windings and a restoring force is exerted on said first pair of Halbach arrays. 7. The track of claim 6, wherein said first pair of Halbach arrays are substantially horizontally oriented, wherein said first component of said first magnetic field and said first component of said second magnetic field comprises a substantially vertical component, wherein said second component of said first magnetic field and said second component of said second magnetic field comprises a substantially horizontal component, wherein said first Halbach array is an upper array, and wherein said second Halbach array is a lower array relative to said upper array. 8. The track of claim 7, further comprising said vehicle attached to said first pair of Halbach arrays. 9. The track of claim 7, wherein due to the downward force of gravity, a midplane between said first pair of Halbach arrays will lie below said track, wherein said restoring force will provide a net levitation force. 10. The track of claim 7, wherein said first pair of Halbach arrays, when moving, have a characteristic lift-to-drag ratio at operating loads, wherein said lift-to-drag ratio can be increased by increasing an area of said first pair of Halbach arrays to decrease the downward displacement required to levitate a given weight, and thus decrease the current required for levitation. 11. The track of claim 7, wherein the current required to levitate said first pair of Halbach arrays may be adjusted by making said lower array to be thinner with respect to said upper array. 12. The track of claim 7, wherein the current required to levitate said first pair of Halbach arrays may be adjusted by making said upper array wider with respect to said lower array. 13. The track of claim 7, further comprising means for separating the function of generation of induced currents in said track from the function of providing levitation. 14. The track of claim 13, wherein said means for separating the function of generation of induced currents in said track from the function of providing levitation comprises adding to said first pair of Halbach arrays a second pair of Halbach array with a magnet orientation such that the components of the field lying in the midplane between each array of said second pair of Halbach arrays cancel, while those perpendicular to the midplane add. 15. The track of claim 14, wherein said second pair of Halbach arrays comprise end pole faces that point in a first direction perpendicular to said arrays, and center pole faces that point in the opposite direction from that of said first direction, and pole faces adjacent to said center pole faces that point toward the center poles of their respective Halbach array of said second pair of Halbach arrays. 16. The track of claim 6, wherein said first Halbach array and said second Halbach array each comprise two outer poles that are pointed towards a midplane between said first Halbach array and said second Halbach array, wherein said first Halbach array and said second Halbach array each comprise a center pole that is pointed away from said midplane and poles adjacent to said center pole that point toward the center pole of the respective array. 17. The track of claim 6, wherein said first pair of Halbach arrays are oriented substantially vertically to provide a centering action. 18. The track of claim 6, wherein the spacing between said first Halbach array and said second Halbach array is adjusted to increase or decrease the field between them, thus varying the levitation current induced in said track. 19. A method for generating a restoring force upon a magnet configuration, comprisingproviding a first Halbach array having a first magnetic field and a second Halbach array having a second magnetic field, wherein said first Halbach array and said second Halbach array are magnetically and structurally connected together to form a first pair of Halbach arrays, wherein said first Halbach array comprises magnet configurations positioned with respect said second Halbach array and said second Halbach array comprises magnet configurations positioned with respect said first Halbach array such that a first component of said first magnetic field and a first component of said second magnetic field substantially cancel at a first plane between said first Halbach array and said second Halbach array, and a second component of said first magnetic field and a second component of said second magnetic field substantially add at said first plane;positioning a track of windings between said first pair of Halbach arrays, wherein said track comprises at least one section of laminated sheets of slotted conductor, wherein said slots are terminated at their ends to provide a path for return currents; andmoving said first pair of Halbach arrays along said track, wherein when said first pair of Halbach arrays move along said track and said track is not located at said first plane, a current is induced in said windings and a restoring force is exerted on said first pair of Halbach arrays. 20. The method of claim 19, wherein each conductor is loaded with ferromagnetic material. 21. The method of claim 19, wherein said at least one section of laminated sheets of slotted conductor comprises a plurality of parallel sections of laminated sheets of slotted conductor. 22. The method of claim 21, wherein said plurality of parallel sections comprises three parallel sections. 23. The method of claim 19, wherein said track is configured to provide a centering force. 24. The method of claim 19, wherein said slots have a length that is at least minimally wider than the width of a levitation magnet assembly on a moving vehicle that rides on said track. 25. The method of claim 19, wherein said first pair of Halbach arrays are substantially horizontally oriented, wherein said first component of said first magnetic field and said first component of said second magnetic field comprises a substantially vertical component, wherein said second component of said first magnetic field and said second component of said second magnetic field comprises a substantially horizontal component, wherein said first Halbach array is an upper array, and wherein said second Halbach array is a lower array relative to said upper array. 26. The method of claim 25, wherein said first pair of Halbach arrays, when moving, have a characteristic lift-to-drag ratio at operating loads, the method further comprising increasing said lift-to-drag ratio by increasing an area of said first pair of Halbach arrays to decrease the downward displacement required to levitate a given weight, and thus decrease the current required for levitation. 27. The method of claim 25, further comprising making said lower array to be thinner with respect to said upper array to adjust the current required to levitate said first pair of Halbach arrays. 28. The method of claim 25, further comprising making said upper array wider with respect to said lower array to adjust the current required to levitate said first pair of Halbach arrays.